alloy powder of a composition formula fe100-a-b-c-d-e-fCoaBbSicPdCueCf having an amorphous phase as a main phase is provided. Parameters satisfy the following conditions: 3.5≤a≤4.5 at %, 6≤b≤15 at %, 2≤c≤11 at %, 3≤d≤5 at %, 0.5≤e≤1.1 at %, and 0≤f≤2 at %. With this composition, the alloy powder has good magnetic characteristics even when it has a large particle diameter such as 90 μm. Therefore, yield thereof is improved.
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1. An alloy powder of a composition formula fe100-a-b-c-d-e-fCoaBbSicPdCueCf having, as a main phase, an amorphous phase or a mixed phase structure of the amorphous phase and a crystal phase of α-fe, wherein:
72.1≤100-a-b-c-d-e-f,
3.5≤a≤4.5 at %,
6≤b≤15 at %,
2≤c≤11 at %,
3≤d≤5 at %,
0.5≤e≤1.1 at %,
0≤f≤2 at %, and
the alloy powder has a particle diameter of 90 μm or less and an fe crystallinity of 25% or lower.
6. The alloy powder as recited in
14. The alloy powder as recited in
6≤b<10 at %,
2<c≤11 at %,
0.5≤e≤1 at %, and
the fe crystallinity is 21% or lower.
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This invention relates to Fe-based amorphous alloy powder which can be used in an electronic component, such as an inductor, a noise filter or a choke coil.
Patent Document 1 proposes alloy powder having an amorphous phase as a main phase. An average particle diameter of the alloy powder of Patent Document 1 is 0.7 μm or more and 5.0 μm or less.
Considering use in an electronic component such as a noise filter or a choke coil, saturation magnetic flux density may be small in comparison with a case of use in a motor, but it is necessary to keep coercive force small and iron loss low. To meet such demands and obtain stably powder having a large particle diameter, it is requested to improve amorphous forming ability of an alloy. When powder is produced from the alloy having the high amorphous forming ability, yield of forming the powder having good characteristics can be improved.
Therefore, the present invention aims to provide alloy powder having high amorphous forming ability.
One aspect of the present invention provides alloy powder of a composition formula Fe100-a-b-c-d-e-fCoaBbSicPdCueCf having, as a main phase, an amorphous phase or a mixed phase structure of the amorphous phase and a crystal phase of α-Fe. Parameters satisfy following conditions: 3.5≤a≤4.5 at %, 6≤b≤15 at %, 2≤c≤11 at %, 3≤d≤5 at %, 0.5≤e≤1.1 at % and 0≤f≤2 at %. In addition, a particle diameter of the alloy powder is 90 μm or less.
Furthermore, another aspect of the present invention provides a magnetic component composed using aforementioned alloy powder.
An FeCoBSiPCu alloy or an FeCoBSiPCuC alloy which includes Co of 3.5 at % or more and 4.5 at % or less has the high amorphous forming ability, and alloy powder having a large particle diameter is easy to be obtained therefrom. The alloy is unsuitable for nano-crystalizing because a ratio of Fe is reduced. On the other hand, the alloy has good magnetic characteristics, i.e. small coercive force and low iron loss, for an electronic component. Therefore, even when powder thereof has a large particle diameter, good magnetic characteristics are obtained, and yield is improved.
While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof will hereinafter be described in detail as an example. It should be understood that the embodiments are not intended to limit the invention to the particular form disclosed, but on the contrary, the intention is to cover all modifications, equivalents and alternatives falling within the spirit and scope of the present invention as defined by the appended claims.
Alloy powder according to an embodiment of the present invention is suitable for use in an electronic component such as a noise filter and is of a composition formula Fe100-a-b-c-d-e-fCoaBbSicPdCueCf, where, 3.5≤a≤4.5 at %, 6≤b≤15 at %, 2≤c≤11 at %, 3≤d≤5 at %, 0.5≤e≤1.1 at %, and 0≤f≤2 at %. In other words, in a case where C is not included, the composition formula is Fe100-a-b-c-d-e-fCoaBbSicPdCue. In a case where C of 0≤f≤2 at % is included, the composition formula is Fe100-a-b-c-d-e-fCoaBbSicPdCueCf.
In the present embodiment, the element Co is an essential element to form an amorphous phase. Adding the element Co of a certain amount to an FeBSiPCu alloy or an FeBSiPCuC alloy, amorphous phase forming ability of the FeBSiPCu alloy or the FeBSiPCuC alloy is improved. Accordingly, alloy powder having a large particle diameter can stably be produced. However, when a ratio of Co is less than 3.5 at %, the amorphous phase forming ability decreases under a liquid quenching condition. As a result, a compound phase is precipitated in the alloy powder, and saturation magnetic flux density decreases. On the other hand, when the ratio of Co is more than 4.5 at %, a rise of coercive force is brought. Accordingly, the ratio of Co is desirable to be 3.5 at % or more and 4.5 at % or less. Even when the ratio of Co is increased to 3.5 at % or more to improve the amorphous phase forming ability, good magnetic characteristics can be obtained by adjusting other elements of B, Si, P and Cu as follows.
In the present embodiment, the element B is an essential element to form the amorphous phase. When a ratio of B is less than 6 at %, the amorphous phase forming ability decreases under the liquid quenching condition. As a result, the compound phase is precipitated in the alloy powder, the saturation magnetic flux density decreases, and the coercive force rises. When the ratio of B is more than 15 at %, the saturation magnetic flux decreases. Accordingly, the ratio of B is desirable to be 6 at % or more and 15 at % or less.
In the present embodiment, the element Si is an essential element to form the amorphous phase. When a ratio of Si is less than 2 at %, the amorphous phase forming ability decreases under the liquid quenching condition. As a result, the compound phase is precipitated in the alloy powder, the saturation magnetic flux density decreases, and the coercive force rises. When the ratio of Si is more than 11 at %, a rise of the coercive force is brought. Accordingly, the ratio of Si is desirable to be 2 at % or more and 11 at % or less.
In the present embodiment, the element P is an essential element to form the amorphous phase. When a ratio of P is less than 3 at %, the amorphous phase forming ability decreases under the liquid quenching condition. As a result, the compound phase is precipitated in the alloy powder, and the coercive force rises. When the ratio of P is more than 5 at %, the saturation magnetic flux density decreases. Accordingly, the ratio of P is desirable to be 3 at % or more and 5 at % or less.
In the present embodiment, the element Cu is an essential element to form the amorphous phase. When a ratio of Cu is less than 0.5 at %, the saturation magnetic flux density decreases. When the ratio of Cu is more than 1.1 at %, the amorphous phase forming ability decreases under the liquid quenching condition. As a result, the compound phase is precipitated in the alloy powder, the saturation magnetic flux density decreases, and the coercive force rises. Accordingly, the ratio of Cu is desirable to be 0.5 at % or more and 1.1 at % or less.
In the present embodiment, the element Fe is a principal element and an essential element to provides magnetism, which occupies the remaining part in the aforementioned compound formula. To improve the saturation magnetic flux density and reduce raw material expenses, it is basically preferable that a ratio of Fe is large. However, when the ratio of Fe is more than 83.5 at %, a large amount of the compound phase is precipitated and the saturation magnetic flux density remarkably decreases in many cases. Furthermore, when the ratio of Fe is more than 79 at %, the amorphous forming ability decreases, and there is tendency of increasing of the coercive force. Accordingly, it is necessary to adjust precisely the ratios of metalloid elements to prevent this. Therefore, it is desirable that the ratio of Fe is 83.5 at % or less and further preferable that the ratio of Fe is 79 at % or less.
The element C may be added to the alloy composition having the aforementioned composition formula Fe100-a-b-c-d-e-fCoaBbSicPdCue by a certain amount to reduce a total material cost. However, when a ratio of C is more than 2 at %, the saturation magnetic flux density decreases. Accordingly, it is desirable that the ratio of C is 2 at % or less (not including zero) even when adding the element C changes the composition formula of the alloy composition into Fe100-a-b-c-d-e-fCoaBbSicPdCueCf.
The alloy powder in the present embodiment may be produced by a water atomization method, a gas atomization method, or grinding a ribbon of an alloy composition.
Furthermore, the alloy powder produced is sieved to be divided into powder having a particle diameter of 90 μm or less and powder having a particle diameter larger than 90 μm. The alloy powder, obtained in this manner, according to the present embodiment has the particle diameter of 90 μm or less, high saturation magnetic flux density of 1.6 T or more, and low coercive force of 100 A/m or less.
Molding the alloy powder according to the present embodiment allows a magnetic core, such as a wound core, a laminated core or a dust core, to be formed. Moreover, using the magnetic core allows an electronic component, such as an inductor, a noise filter, or a choke coil, to be provided.
Hereinafter, the embodiment of the present invention will be described in more detail with reference to a plurality of examples and a plurality of comparative examples.
At first, FeCoBSiPCu alloys which did not include C were tested. In detail, materials were weighed to obtain alloy compositions of examples 1 to 11 of the present invention and comparative examples 1 to 10 listed in a table 1, and mother alloys were produced by melting the weighed materials with high frequency induction melting treatment. Each of the mother alloys was processed with a gas atomization method, and powder was obtained. Discharge quantity of alloy molten metal was set to 15 g/sec or less in average while gas pressure was set to 10 MPa or more. The powder obtained by this manner was sieved to be divided into powder having a particle diameter of 90 μm or less and powder having a particle diameter larger than 90 μm, and the alloy powder of each of the examples 1 to 11 and the comparative examples 1 to 10 was obtained. Saturation magnetic flax density Bs of the alloy powder of each example was measured in a magnetic field of 800 kA/m using a vibrating sample magnetometer (VSM). Coercive force Hc of the alloy powder of each example was measured in a magnetic field of 23.9 kA/m (300 oersted) using a direct current BH tracer. Measurement results are shown in a table 2.
TABLE 1
Fe
Co
B
Si
P
Cu
Example 1
79.7
3.6
8
4
4
0.7
Example 2
79.3
4
8
4
4
0.7
Example 3
78.7
4.5
8
4
4
0.8
Comparative
80
3.3
8
4
4
0.7
Example 1
Comparative
78.6
4.7
8
4
4
0.7
Example 2
Example 4
81.2
4
6.2
4
4
0.6
Example 5
72.5
4
14.8
4
4
0.7
Comparative
81.4
4
5.9
4
4
0.7
Example 3
Comparative
71.9
4
15.3
4
4
0.8
Example 4
Example 6
81.2
4
8
2
4
0.8
Example 7
72.1
4.2
8
11
4
0.7
Comparative
79.6
3.9
10
1.8
4
0.7
Example 5
Comparative
73.3
4.4
6
11.5
4
0.8
Example 6
Example 8
78
4.1
10
4
3.2
0.7
Example 9
79.6
3.8
8
3
5
0.6
Comparative
80.5
4
8
4
2.8
0.7
Example 7
Comparative
76.6
4.3
9
4.1
5.2
0.8
Example 8
Example 10
78.4
3.9
9
4.2
4
0.5
Example 11
79
4
8
4
4
1
Comparative
77.7
4
10
4
4
0.3
Example 9
Comparative
79
4.2
8
4
3.6
1.2
Example 10
TABLE 2
Saturation
Magnetic
Fe
flux
Coercive
90 μm and below
Crystallinity
Density
Force
Powder Structure
(%)
(T)
(A/m)
Example 1
Amo. + Fe
19
1.72
84.7
Example 2
Amo.
—
1.67
76.3
Example 3
Amo.
—
1.65
67.9
Comparative
Amo. + Fe + Comp.
17
1.52
109.2
Example 1
Comparative
Amo. + Fe
21
1.58
147
Example 2
Example 4
Amo. + Fe
25
1.73
99.1
Example 5
Amo.
—
1.61
42.1
Comparative
Amo. + Fe + Comp.
16
1.55
152.3
Example 3
Comparative
Amo. + Fe
3
1.56
157.2
Example 4
Example 6
Amo. + Fe
23
1.81
97.6
Example 7
Amo.
—
1.64
34.7
Comparative
Amo. + Fe + Comp
15
1.5
159.6
Example 5
Comparative
Amo. + Fe
18
1.56
143.5
Example 6
Example 8
Amo.
—
1.67
72.8
Example 9
Amo. + Fe
21
1.77
79.1
Comparative
Amo. + Fe + Comp.
12
1.57
142.1
Example 7
Comparative
Amo.
15
1.5
96.3
Example 8
Example 10
Amo.
—
1.65
72.8
Example 11
Amo. + Fe
24
1.71
79.1
Comparative
Amo. + Fe
6
1.37
98
Example 9
Comparative
Amo. + Fe + Comp.
11
1.55
143.4
Example 10
As understood from the table 2, the alloy powder of each of the examples 1 to 11 had an amorphous phase as a main phase or had a mixed phase structure of the amorphous phase and a crystal phase of α-Fe. In contrast, the alloy powder of each of the comparative examples 1, 3, 5, 7 and 10 included a compound phase. Moreover, the alloy powder of each of the examples 1 to 11 had small coercive force of 100 A/m or less and high saturation magnetic flux density of 1.6 T or more. In contrast, the alloy powder of each of the comparative examples 1 to 10 had the saturation magnetic flux density lower than 1.6 T or had the coercive force remarkably larger than 100 A/m. Thus, according to the invention, without nano-crystalizing by means of heat treatment, small coercive force and high saturation magnetic density can be achieved.
Furthermore, FeCoBSiPCuC alloys including C were tested. In detail, the materials were weighed to obtain alloy compositions of examples 12 to 14 of the present invention and a comparative example 11 listed in a table 3, and mother alloys were produced by melting the weighed materials with the high frequency induction melting treatment. Each of the mother alloys was processed with the gas atomization method, and powder was obtained. The discharge quantity of the alloy molten metal was set to 15 g/sec or less in average while the gas pressure was set to 10 MPa or more. The powder obtained by this manner was sieved to be divided into powder having a particle diameter of 90 μm or less and powder having a particle diameter larger than 90 μm, and the alloy powder of each of the examples 12 to 14 and the comparative example 11 was obtained. The saturation magnetic flux density Bs of the alloy powder of each example was measured in the magnetic field of 800 kA/m using the vibrating sample magnetometer (VSM). The coercive force Hc of the alley powder of each example was measured in the magnetic field of 23.9 kA/m (300 oersted) using the direct current BH tracer. Measurement results are shown in a table 4.
TABLE 3
Fe
Co
B
Si
P
Cu
C
Example 12
78.4
4.2
8
4
4
0.8
0.6
Example 13
78.1
4
8.2
4
4
0.7
1
Example 14
76.1
3.9
9
4.2
4.1
0.8
1.9
Comparative
76.2
4
9
4
4
0.7
2.1
Example 11
TABLE 4
Saturation
Magnetic
Fe
flux
Coercive
90 μm and below
Crystallinity
Density
Force
Powder Structure
(%)
(T)
(A/m)
Example 12
Amo. + Fe
18
1.66
67.2
Example 13
Amo. + Fe
10
1.63
62.3
Example 14
Amo.
—
1.62
53.6
Comparative
Amo. + Fe
15
1.49
57.4
Example 11
As understood from the table 4, the alloy powder of each of the examples 12 to 14 had the amorphous phase as the main phase or had the mixed phase structure of the amorphous phase and the crystal phase of α-Fe. Moreover, the alloy powder of the examples 12 to 14 had the small coercive force of 100 A/m or less and the high saturation magnetic flux density of 1.6 T or more. In contrast, the alloy powder of the comparative example 11 had low saturation magnetic flux density.
The present invention is based on a Japanese patent application of JP2014-147249 filed before the Japan Patent Office on Jul. 18, 2014, the content of which is incorporated herein by reference.
While there has been described what is believed to be the preferred embodiment of the invention, those skilled in the art will recognize that other and further modifications may be made thereto without departing from the spirit of the invention, and it is intended to claim all such embodiments that fall within the true scope of the invention.
Nishiyama, Nobuyuki, Makino, Akihiro, Takenaka, Kana, Sharma, Parmanand
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